Apparatus utilizing buoyancy forces

ABSTRACT

An apparatus has a base and a flow path assembly movably supported by the base and defining a serpentine flow path having an entry opening and an exit opening. An actuator is coupled with the flow path assembly and the base and is configured to rotate the flow path assembly between a vertical and an angled position relative to the base. The flow path is configured to allow a column of a first fluid with a first density to be trapped between columns of a second fluid with a second density higher than the first density. The first fluid column has a first height and the second fluid columns have second heights, so that a volume of the first fluid and a volume of the second fluid flow through the flow path and through the exit opening as the flow path assembly is rotated between the vertical and angled positions.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application Ser.No. 61/716,213, filed on Oct. 19, 2012, the contents of which areexpressly incorporated herein by reference.

BACKGROUND

The inventive concepts disclosed herein generally relate to an apparatusfor utilizing buoyancy forces and to methods of using the same. Moreparticularly, but not by way of limitation, the inventive conceptsdisclosed herein relate to an apparatus for utilizing buoyancy forces bymultiplying the lift of several alternating columns of a first fluid anda second fluid over several surfaces, and to methods of using the same.

The properties of buoyancy have been explored as a source of renewableor “green” energy because of the ability to use buoyancy forces inexisting bodies of water without generating additional environmentalpollution and greenhouse gases.

Existing prior art buoyancy devices typically depend on utilizing thebuoyancy energy of waves, or moving waters, and as such have limitedapplications, as they must be installed at certain locations where wavesor moving waters are available in order to work. Further, such prior artdevices do not produce a consistent level of power, as the power outputof such prior art devices is subject to fluctuations in waves, tides,and to seasonal water level variations.

Another problem with currently existing buoyancy devices is that theyare often complicated and have multiple components, which requirefrequent maintenance and replacement, and are expensive to implement andoperate. Further, such complicated devices often suffer from lowefficiency and are generally unreliable due to their overcomplicateddesigns.

SUMMARY

In one aspect, the inventive concepts disclosed herein are directed toan apparatus including a base and a flow path assembly movably supportedby the base and defining a substantially serpentine flow path having anentry opening and an exit opening. An actuator is coupled with the flowpath assembly and with the base, the actuator configured to rotate theflow path assembly between a substantially vertical position and anangled position relative to the base. The substantially serpentine flowpath is configured to allow a column of a first fluid with a firstdensity to be trapped between two columns of a second fluid with asecond density higher than the first density, the first fluid columnhaving a first height and the second fluid columns having secondheights, so that a first volume of the first fluid and a second volumeof the second fluid flow in and out the serpentine flow path through theexit opening as the flow path assembly is rotated between thesubstantially vertical position and the angled position.

In a further aspect, the inventive concepts disclosed herein aredirected to an apparatus including a base and a frame movably supportedby the base. The frame has a first side and a second side cooperating todefine a rotation plane and a rotation axis extending substantiallyparallel to the rotation plane, the frame being rotatable between asubstantially vertical position and an angled position about therotation axis.

An actuator assembly is coupled with the frame and with the base and isconfigured to rotate the frame about the rotation axis between thesubstantially vertical position and the angled position relative to thebase.

A flow path assembly includes a first conduit having a first upper endand a first lower end and being connected to the frame so that the firstconduit extends substantially vertically when the frame is in thesubstantially vertical position. A second conduit having a second upperend and a second lower end is connected to the frame so that the secondconduit extends substantially vertically when the frame is in thesubstantially vertical position. A third conduit having a third upperend and a third lower end is connected to the frame so that the thirdconduit extends substantially vertically when the frame is in thesubstantially vertical position. A fourth conduit having a fourth upperend and a fourth lower end is connected to the frame so that the fourthconduit extends substantially vertically when the frame is in thesubstantially vertical position.

The flow path assembly also has a first connector conduit fluidlyconnected with the first lower end of the first conduit and the secondlower end of the second conduit, the first connector conduit having afirst fluid passage formed therein and configured to allow one or morefluids to be introduced into, or removed from, the first and the secondconduits. A second connector conduit is fluidly connected with thesecond upper end of the second fluid conduit and the third upper end ofthe third conduit, the second connector conduit having a second fluidpassage formed therein and configured to allow one or more fluids to beintroduced into or removed from the second connector conduit. A thirdconnector conduit is fluidly connected with the third lower end of thethird conduit and the fourth lower end of the fourth conduit, the thirdconnector conduit having a third fluid passage formed therein andconfigured to allow one or more fluids to be introduced into or removedfrom the third connector conduit. An exit conduit is fluidly connectedwith the fourth upper end such that the first, second, third, and fourthconduits, the first, second, and third connector conduits, and the exitconduit, cooperate to define a substantially serpentine flow path.

The substantially serpentine flow path is configured to allow a columnof a first fluid with a first density to be trapped between two columnsof a second fluid with a second density higher than the first density,the first fluid column having a first height and the second fluidcolumns having second heights, so that a first volume of the first fluidand a second volume of the second fluid flow in and out the serpentineflow path through the exit conduit as the frame is rotated between thesubstantially vertical position and the angled position.

BRIEF DESCRIPTION OF THE DRAWINGS

Like reference numerals in the figures may represent and refer to thesame or similar element or function. Implementations of the disclosuremay be better understood when consideration is given to the followingdetailed description thereof. Such description makes reference to theannexed pictorial illustrations, schematics, graphs, drawings, andappendices. In the drawings:

FIG. 1 is a perspective view diagram of an exemplary embodiment of atiltable apparatus according to the inventive concepts disclosed herein.

FIG. 2 is a side view diagram of the apparatus of FIG. 1.

FIG. 3 is a perspective view diagram of an exemplary embodiment of atiltable apparatus according to the inventive concepts disclosed hereinshown in a substantially vertical position.

FIG. 4 is a perspective view diagram of the apparatus of FIG. 3 shown ina tilted position.

FIG. 5 is a side view diagram of an exemplary embodiment of a supportassembly according to the inventive concepts disclosed herein.

FIG. 6 is an end view of the support assembly of FIG. 5.

FIG. 7 is a side view diagram of a frame assembly according to theinventive concepts disclosed herein.

FIG. 8 is a partial perspective view of the frame assembly of FIG. 7.

FIG. 9 is an end view of the frame assembly of FIG. 7.

FIG. 10 is a side view diagram of an embodiment of an actuator assemblyaccording to the inventive concepts disclosed herein shown connected toa shaft.

FIG. 11A is a side view diagram of an exemplary embodiment of anapparatus according to the inventive concepts disclosed herein.

FIG. 11B is a side view diagram of the apparatus of FIG. 11A.

FIG. 12A is a side view diagram of an exemplary embodiment of a rotaryapparatus according to the inventive concepts disclosed herein.

FIG. 12B is a side view diagram of the rotary apparatus of FIG. 12A.

FIG. 13A is a side view diagram of an exemplary embodiment of a rotaryapparatus according to the inventive concepts disclosed herein.

FIG. 13B is a side view diagram of the rotary apparatus of FIG. 13A.

DETAILED DESCRIPTION

Before explaining at least one embodiment of the inventive conceptsdisclosed herein in detail, it is to be understood that the inventiveconcepts are not limited in their application to the details ofconstruction and the arrangement of the components or steps ormethodologies set forth in the following description or illustrated inthe drawings. The inventive concepts disclosed herein are capable ofother embodiments or of being practiced or carried out in various ways.Also, it is to be understood that the phraseology and terminologyemployed herein is for the purpose of description only and should not beregarded as limiting the inventive concepts disclosed and claimed hereinin any way, unless expressly stated to the contrary.

In the following detailed description of embodiments of the inventiveconcepts, numerous specific details are set forth in order to provide amore thorough understanding of the inventive concepts. However, it willbe apparent to one of ordinary skill in the art that the inventiveconcepts disclosed herein may be practiced without these specificdetails. In some instances, well-known features have not been describedin detail to avoid unnecessarily complicating the instant disclosure.

As used herein the notation “a-n” appended to a reference numeral isintended as merely convenient shorthand to reference one, or more thanone, and up to infinity, of the element or feature identified by therespective reference numeral (e.g., 100 a-n). Similarly, a letterfollowing a reference numeral is intended to reference an embodiment ofthe feature or element that may be similar, but not necessarilyidentical, to a previously described element or feature bearing the samereference numeral (e.g., 100, 100 a, 100 b, etc.). Such shorthandnotations are used for purposes of clarity and convenience only, andshould not be construed to limit the instant inventive concepts in anyway, unless expressly stated to the contrary.

Further, unless expressly stated to the contrary, “or” refers to aninclusive or and not to an exclusive or. For example, a condition A or Bis satisfied by anyone of the following: A is true (or present) and B isfalse (or not present), A is false (or not present) and B is true (orpresent), and both A and B are true (or present).

In addition, use of the “a” or “an” are employed to describe elementsand components of the embodiments herein. This is done merely forconvenience and to give a general sense of the inventive concepts. Thisdescription should be read to include one or at least one, and thesingular also includes the plural, unless it is obvious that it is meantotherwise.

As used herein, the term “fluid,” and any variations thereof, isintended to include a compressible or a substantially non-compressiblefluid (e.g., gas or liquid), such as water, mineral oil, mercury,metals, plant-based oils, animal-based oils, petroleum-based oils,synthetic oils, alcohols, solutions, suspensions, gels, viscous liquids,liquid chemicals, vapors, liquefied gasses, semi-solids or solids, andcombinations thereof, for example. The term “fluid” is not necessarilyintended to be understood as an absolute term, and may refer to asubstance being a fluid at a range of pressures, temperatures, or otheroperating conditions typically encountered by an apparatus constructedaccording to the inventive concepts disclosed herein.

As used herein the terms “compressible” and “substantiallynon-compressible” are not necessarily intended to be understood asabsolute terms, and may refer to the fluid being compressible ornon-compressible at a range of pressures, temperatures, or otheroperating conditions typically encountered by an apparatus constructedaccording to the inventive concepts disclosed herein.

Finally, as used herein any reference to “one embodiment” or “anembodiment” means that a particular element, feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment. The appearances of the phrase “in oneembodiment” in various places in the specification are not necessarilyall referring to the same embodiment.

In exemplary embodiments of the inventive concept disclosed herein anapparatus may be configured to change the pressure in a controlledvolume of a first fluid having a first density positioned between twocolumns of a second fluid having a second density which is larger thanthe first density. The apparatus may include a tilting or rotating framerotatably supported by a base. The frame may be rotatable between asubstantially vertical position and an angled or tilted position. Thetwo fluids may be placed in a conduit attached to the frame, the conduitforming two or more loops and defining an overall substantiallyserpentine (or substantially S-shaped) flow path, with columns of thefirst fluid and the second fluid alternating with one another in theserpentine flow path so as to trap one or more columns of the firstfluid between one or more columns of the second fluid. Alternatively,the two fluids may be placed in a flow path defined by the frame, suchas a molded frame defining an overall substantially serpentine (orsubstantially S-shaped) flow path, with columns of the first fluid andthe second fluid alternating with one another in the serpentine flowpath so as to trap one or more columns of the first fluid between one ormore columns of the second fluid. In some exemplary embodiments, thefirst fluid may be a gas, such as air, and the second fluid may be aliquid, such as water.

As the frame is rotated from the substantially vertical position towardsthe angled position, the fluid column heights of the first fluid and thesecond fluid decrease, so as to decrease the pressures exerted by thealternating columns of the first fluid and the second fluid onto oneanother. As the frame is rotated from the angled position towards thesubstantially vertical position, the fluid column heights of the firstand the second fluid increase, so as to increase the pressures exertedby the alternating columns of the first fluid and the second fluid ontoone another. A volume of the first or the second fluid may be withdrawnfrom or may flow out of the apparatus when the frame is in thesubstantially vertical position (e.g., the fluids are at relatively highpressures), and a volume of the first or second fluid may be introducedor may flow into the apparatus when the frame is in the angled position(e.g., the fluids are at relatively low pressures).

It is to be understood that the first fluid and the second fluid may beliquids, liquid metals, gels, gasses, liquefied gasses, solutions,suspensions, viscous slurries, emulsions, foams, gels, porous solids orsemi-solids, and combinations or mixtures thereof, including a mixtureof two or more liquids, fluids, gasses, or solids or semi-solids.Further, in some exemplary embodiments the first fluid and the secondfluid may be substantially non-compressible, while is some exemplaryembodiments the first fluid may be substantially non-compressible andthe second fluid may be compressible, the first fluid may becompressible, and the second fluid may be substantiallynon-compressible, or both the first and the second fluid may becompressible.

The inventive concepts disclosed herein will be described in detail inconnection with exemplary embodiments in which the first fluid is air,and the second fluid is water. It is to be understood that the inventiveconcepts disclosed herein are not limited to using water or air, and maybe implemented with any suitable first fluid (or mixture of fluids)having a first density, and second fluid (or mixture of fluids) having asecond density, where the first density and the second density aredifferent from one another, regardless of whether the first density islarger than, or smaller than the second density. Such first and secondfluids may be compressible or substantially incompressible fluids, forexample.

The greater the difference between the first density and the seconddensity, the greater the efficiency of an apparatus according to theinventive concepts disclosed herein is expected to be. As a practicalmatter, using two substantially non-compressible fluids having arelatively large density difference would be expected to result in ahigher efficiency, than using two compressible fluids having arelatively small density difference.

However, practical consideration may favor designing an apparatusaccording to the inventive concepts disclosed herein that uses cheap,safe, and readily available fluids such as air and water, for example,to minimize the cost of constructing and operating the apparatus,disposing of fluids during set-up, maintenance, transport, or repair ofthe apparatus, and to avoid using fluids that may be hazardous topeople, animals, or the environment, for example. Similarly, where anapparatus according to the inventive concepts disclosed herein is to beinstalled in environments where freezing or hot temperatures areexpected, the first and second fluids selected may be freeze-resistant,or evaporation-resistant, for example.

As another example, inert gasses may be implemented as the first or thesecond fluid, instead of atmospheric air, such as argon, helium,nitrogen, carbon dioxide, and combinations thereof, for example.Further, a variety of chemical or biocidal additives may be added to thefluids used with an apparatus according to the inventive conceptsdisclosed herein, so as to prevent the growth of organisms inside theapparatus, such as bacteria, for example.

Referring now to FIGS. 1-2, an exemplary embodiment of an apparatus 100constructed in accordance with the inventive concepts disclosed hereinmay include a support assembly 102, a frame assembly 104 rotatablysupported by the support assembly 102, a flow path assembly 106connected to the frame assembly 104 and defining a substantiallyS-shaped or serpentine flow path 108, and an actuator assembly 110operably coupled with the frame assembly 104 and configured to tilt orrotate the frame assembly 104 relative to the support assembly 102.

The support assembly 102 may include two or more support members 112extending substantially vertically from a base 114. While the two ormore support members 112 are shown as extending substantially verticallyfrom the base 114 and as being substantially parallel to one another, insome exemplary embodiments the two or more support members 112 may beoriented at any desired angle towards one another and relative to thebase 114. The two or more support members 112 may have openings 116formed therein, the openings 116 adapted to rotatably receive a shaft118 of the frame assembly 104 therein. It is to be understood that insome exemplary embodiments one support member 112 or more than twosupport members 112 may be used with the inventive concepts disclosedherein.

The support assembly 102 may be constructed of any suitable materialconfigured to support the weight of the frame assembly 104, the flowpath assembly 106, and the actuator assembly 110, for example. Suitablematerials of which the support assembly 102 may be constructed in someexemplary embodiments may include metals, non-metals, resilientplastics, alloys, polymers, steel, aluminum, titanium, resins, wood, orcombinations thereof, for example.

The frame assembly 104 may be implemented as any suitable frame assembly104 configured to support the weight of the flow path assembly 106 sothat the flow path assembly 106 may be rotated or tilted relative to thesupport assembly 102, for example. The frame assembly 104 may include ashaft 118 rotatably connected with the two or more support members 112of the support assembly 102, for example. The shaft 118 may be rotatablyconnected to the two or more support members 112 in any suitable manner,including via bearings (not shown), fittings (not shown), flanges (notshown), or combinations thereof, for example, and the shaft 118 may atleast partially or completely extend through the two or more supportmembers 112 in some exemplary embodiments.

The frame assembly 104 may further have a rotation axis 120 (FIG. 1),such that the shaft 118 extends along the rotation axis 120 in someexemplary embodiments. The rotation axis 120 may extend substantiallythrough a center of gravity (not shown) of the frame assembly 104, suchthat rotating the frame assembly 104 about the rotation axis 120 may beachieved easily and cheaply in terms of energy. It so be understood thatdue to shifting columns of fluid in the flow path 108, the actual centerof gravity of the frame assembly 104 may shift during tilting orrotation of the frame assembly 104 about the rotation axis 120.

The frame assembly 104 may be constructed of any suitable material, suchas metals, steel, aluminum, titanium, alloys, resilient plastic,thermoset materials, resins, non-metals, or combinations thereof, forexample.

The flow path assembly 106 may be implemented as any suitable flow pathassembly 106 defining a substantially S-shaped or substantiallyserpentine flow path 108. For example, as shown in FIGS. 1-2, the flowpath assembly 106 may include a plurality of substantially U-shapedconduits 122 a-n fluidly connected in series and alternating inorientation relative to one another, so as to cooperate and define thesubstantially S-shaped flow path 108. A first conduit 122 a-n may havean entry opening 124 which may be open to the atmosphere, and a secondconduit 122 a-n may be fluidly connected with an exit conduit 126, forexample. The conduits 122 a-n may have any desired size, shape,cross-section, construction, or combinations thereof, for example.

It is to be understood that while four conduits 122 a-n are shown inFIG. 1, the inventive concepts disclosed herein may be implemented withany desired number of conduits 122 a-n, such as two, three, five, six,or more conduits 122 a-n fluidly connected with one another so as tocooperate and define the substantially S-shaped flow path 108, forexample. Further, while the conduits 122 a-n are shown as beingsubstantially coplanar with one another, in some exemplary embodimentstwo or more conduits 122 a-n may be non-coplanar, and may be angledrelative to one another at any angle such as an angle varying betweenabout 0° and about 90°, for example.

It is to be understood that while the flow path assembly 106 has beendescribed herein as including conduits 122 a-n connected to the frameassembly 104, the inventive concepts disclosed herein are not limited tousing conduits 122 a-n. For example, in some embodiments, the flow pathassembly 106 may be implemented as a molded-type flow path assembly 106defining an internal substantially S-shaped flow path 108, for example.In some exemplary embodiments, the flow path assembly 106 may beinjection molded, cast, machined, molded, or combinations thereof, andmay be constructed of any suitable materials such as metals, alloys,non-metals, polymers, thermoplastics, plastics, fibrous materials,carbon fiber, or combinations thereof.

The conduits 122 a-n may be implemented as any suitable conduits 122a-n, such as pipes, hoses, or other desirable conduits 122 a-n, and maybe made of any desired material, such as PVC, plastics, Plexiglas,metals, alloys, non-metals, resins, or combinations thereof. In someexemplary embodiments of the inventive concepts disclosed herein, atleast a portion of the conduits 122 a-n may be substantiallytransparent, such that a height of the first fluid column 140 and thesecond fluid column 142 inside the conduits 122 a-n may be visuallyobserved. In an exemplary embodiment of the inventive concepts disclosedherein, the conduits 122 may be substantially opaque, and one or moresight port (not shown), sight glass (not shown), fluid-level gauge (notshown), another fluid-level indicating device, or combinations thereof,may be implemented to monitor the heights of the first fluid columns 140and the second fluid columns 142 inside the conduits 122 a-n.

Further, in some exemplary embodiments of the inventive conceptsdisclosed herein, the flow path assembly 106 and the frame assembly 104may be formed as a unitary body, for example, by incorporating the shaft118 into the flow path assembly 106, as will be appreciated by personsof ordinary skill in the art having the benefit of the instantdisclosure.

The exit conduit 126 may be fluidly connected with an optional tank 128.The optional tank 128 may be fluidly connected with an output conduit130, which may be selectively partially or substantially completelyclosed by a valve 132, for example. It is to be understood that in someexemplary embodiments the tank 128 may be omitted and the exit conduit126 may be fluidly connected to any desired vessel, conduit, system,assembly, tank, or combinations thereof. Further, in some exemplaryembodiments, the valve 132 may be omitted, or may be replaced with anysuitable mechanism configured to selectively allow a fluid to flowthrough the output conduit 130, or to selectively substantially preventa fluid from flowing through the output conduit 130, as will be readilyappreciated by a person of ordinary skill in the art having the benefitof the instant disclosure.

The flow path assembly 106 may be connected to the frame assembly 104 inany suitable manner, such as via using adhesives, bolts, clamps,brackets, flanges, screws, welds, seams, joints, or combinationsthereof, so that the flow path assembly 106 may be supported by theframe assembly 104 and may rotate relative to the support assembly 102along with the frame assembly 104, for example.

In the exemplary embodiment of FIGS. 1-2, the actuator assembly 110 isshown as a lever 134 connected to the shaft 118 of the frame assembly104. The lever 134 may be operated to tilt the frame assembly 104relative to a horizontal plane at any desired angle (e.g., between about0° and about 180°), as will be described below. The actuator assembly110 is configured to selectively pivot, tilt, rotate, or otherwise movethe frame assembly 104 and the flow path assembly 106 relative to ahorizontal plane (not shown), so as to move the flow path 108 between asubstantially vertical position where the flow path 108 is substantiallyperpendicular to the horizontal plane, and an angled position, whereinthe flow path 108 is angled relative to the horizontal plane (e.g., atan angle different from about 90°), for example.

It is to be understood that an actuator assembly 110 according to theinventive concepts disclosed herein may be implemented as any suitableactuator assembly 110, including a manual, a hydraulic, a pneumatic, amechanical, a magnetic, an electrical actuator assembly 110, orcombinations thereof, for example. The actuator assembly 110 has beendescribed as a manual actuator assembly 110 for purposes of clarity andsimplicity only, and is not limited to a manual actuator assembly 110.In a commercial implementation of an apparatus 100 according to theinventive concepts disclosed herein, the actuator assembly 110 may beautomated and may be controlled by a processor executing processorexecutable code stored in a non-transitory computer medium, for example.

The apparatus 100 may be configured to change the pressure in acontrolled volume of fluid between a specified high and low pressurequickly and easily through a reversible and repeatable process. In someexemplary embodiments, the apparatus 100 may be set up and may operateas follows:

The one or more first fluid column 140 and one or more second fluidcolumn 142 may be positioned in the flow path 108, so that the firstfluid column 140 and the second fluid column 142 alternate with oneanother, such that a first fluid column 140 is trapped between twosecond fluid columns 142, for example. The first fluid may have a firstdensity, and the second fluid may have a second density, such that thefirst density is lower than the second density, so that the first fluidcolumn 140 may be trapped between, surrounded by, or positioned between,two second fluid columns 142, for example. As can be seen in FIG. 1, theheights of the one or more first fluid column 140 and the heights of theone or more second fluid column 142 may differ between the conduits 122a-n, and are not necessarily equal in each conduit 122 a-n, for example.

The apparatus 100 may be initialized by filling alternating conduits 122a-n between about 50% and about 95% and between about 5% and about 50%full of the second fluid, respectively. In some exemplary embodiments,the conduits 122 a-n may be filled to any desired volume or amount, suchas between about 0% and about 100%, and any ranges and sub-rangestherebetween. The exact second fluid column 142 heights in each of theconduits 122 a-n are dependent on the pressure desired to be outputtedby the apparatus 100.

Next, a volume of the first fluid may be injected or otherwiseintroduces into the conduits 122 a-n (e.g., via valves or ports), sothat one or more first fluid columns 140 are positioned or trappedbetween two second fluid columns 142. The volume of the first fluidintroduced may be varied for each conduit 122 a-n, according topredetermined volumes, which may be marked on the apparatus itself(e.g., a scale, or sight-glass markings) or may be supplied with amanual or set-up procedure guide provided with the apparatus 100, forexample. The volume of first fluid may be introduced into the conduits122 a-n in any order, such as sequentially, randomly, or semi-randomly,for example. This may result in a setup where the pressure in eachconduit 122 a-n is different throughout the apparatus 100 (e.g., thepressures increase from the entry opening 124 towards the exit conduit126), with the initial pressure in the entry opening 124 beingsubstantially atmospheric and the pressure inside the substantiallyS-shaped flow path 108 increasing in each subsequent alternating firstfluid column 140 and second fluid column 142 to the desired finalpressure at the exit conduit 126, for example. The final pressure at theexit conduit 126 may be substantially equal to the sum of the pressuresof the first fluid columns 140 and second fluid columns 142 positionedin the substantially S-shaped flow path 108, for example.

While the pressure for the initial setup may be created by adding afirst relatively less dense fluid (e.g., air or gas) into each conduit122 a-n, the pressure at any point in the apparatus 100 can easily bemeasured by visually inspecting differences in the heights of the second(relatively more dense) fluid columns 142 in a relatively high-pressureside and a relatively low-pressure side of each conduit 122 a-n. Theinitial setup is designed to have enough pressure to produce the desiredoutput pressure in the exit conduit 126, while also having enough extrasecond fluid column 142 height to ensure that during operation thesecond fluid is not able to flow over the top of the conduits 122 a-n orfor the first fluid to be pushed under the conduits 122 a-n.

The apparatus 100 operates by changing the pressure of a column of fluidbetween two different values by being moved between the substantiallyvertical position (FIG. 1) and the angled position (FIG. 2). Thepressure change may be a result of the changing gravity effects on thefirst fluid column 140 and the second fluid column 142 as theirrespective heights change when the apparatus 100 is rotated between thesubstantially vertical position shown in FIG. 1 and the angled positionshown in FIG. 2. For example, the relatively maximum gravity effect onthe height of the first fluid column 140 and the second fluid column 142is exerted when the first fluid column 140 and the second fluid column142 are in the substantially vertical position (FIG. 1), and therelatively minimum gravity effect on the first fluid column 140 and thesecond fluid column 142 is exerted when the first fluid column 140 andthe second fluid column 142 are in an angled position (FIG. 2), e.g.,where the fluid columns 140 and 142 are substantially horizontal. Thepressure change is accomplished by tilting or rotating the apparatus 100from the substantially vertical position to the angled position (e.g.,between about 0° and about 90°, or between about 0° and about 108°)about the rotation axis 120. The exact angle of rotation between thesubstantially vertical position and the angled position may depend onthe difference between the higher and lower pressures desired, forexample.

This rotation of the flow path assembly 106 can be implemented via theactuator assembly 110. It is to be understood that any suitable actuatorassembly 110 or method may be used to effect the rotation of the flowpath assembly 106, and the optimal rotation may be dependent on theparticular application for which the apparatus 100 is used. For example,a hydraulic actuator mechanism (not shown), a magnetic actuatormechanism (not shown), a mechanical actuator mechanism (not shown), apneumatic actuator mechanism (not shown), and electrical actuatormechanism (not shown), or combinations thereof may be implemented.

After initialization, the apparatus 100 is operated by removing a volumeof fluid from the tank 128 while the flow path assembly 106 issubstantially in the vertical (or high-pressure) position. The actuatorassembly 110 may then be operated to rotate the flow path assembly 106to the low-pressure position, and a volume of the second fluid that isadded back in to the apparatus 100 as after the flow path assembly 106is moved towards the angled (or low-pressure) position. This process canbe repeated for as long as desired.

Referring now to FIGS. 3-4, an exemplary embodiment of an apparatus 100a according to the inventive concepts disclosed may be implemented andfunction similarly to the apparatus 100, and may include a supportassembly 102 a, a frame assembly 104 a rotatably supported by thesupport assembly 102 a, a flow path assembly 106 a connected to theframe assembly 104 a and defining a substantially S-shaped or serpentineflow path 108 a, and an actuator assembly (not shown), such as theactuator assembly 110 may be operably coupled with the frame assembly104 a and configured to tilt or rotate the frame assembly 104 a relativeto the support assembly 102 a, for example.

The support assembly 102 a may be implemented similarly to the supportassembly 102 and may include four or more support members 112 aextending substantially vertically from a base 114 a, for example. Thesupport members 112 a and the base 114 a may be connected in anysuitable manner, such as via fasteners, bolts, screws, welds, joints,seams, adhesives, brackets, clamps, or combinations thereof, forexample.

As can be seen in FIGS. 5-6, two support members 112 a may be connectedto a base 114 a, but it is to be understood that each support member 112a may be connected to a base 114 a, or three, four, or more supportmembers 112 a may be connected to a base 114 a, for example. Further insome exemplary embodiments any desired number of support members 112 amay be used, and in some exemplary embodiments the base 114 a may beomitted. An optional stabilization plate (not referenced) may be used tosecurely connect the four support members 112 a to the base 114 a, forexample.

One or more optional stabilizing plates 150 may be used to connect twoor more support members 112 a, so as to increase the rigidity andstrength of the support assembly 102 a, as will be appreciated by aperson of ordinary skill in the art having the benefit of the instantdisclosure.

A first and a second mounting plate 152 may be connected to two or moresupport members 112 a (only one being shown in FIGS. 3-4), with thefirst and the second mounting plate 152 being oriented substantiallyparallel to one another and being supported by support members 112 a ata distance from one another, for example, so as to allow the frameassembly 104 a to be rotatably connected to the support assembly 102 a.

A mounting bracket 154 (e.g., a bearing) may be implemented with eachmounting plate 152 so as to rotatably receive a shaft 118 a of the frameassembly 104 a therein, for example. An elongated slot 156 may be formedin the mounting bracket 154 and may be configured to allow for theheight of the mounting bracket 154 relative to the base 114 a to beadjusted as desired. The mounting bracket 154 may further include aplurality of corresponding openings 158 formed adjacent to the slot 156so that the position of the mounting brackets 154 on the first and thesecond mounting plates 152 may be correspondingly adjusted by securing arespective mounting bracket 154 at the same height on each mountingplate 152 (e.g., by inserting fasteners through the correspondingopenings 158). It is to be understood that in some exemplary embodimentthe mounting bracket 154 may be omitted, and the shaft 118 a may berotatably connected with the support assembly 102 a in any desiredmanner, as will be appreciated by a person of ordinary skill in the arthaving the benefit of the instant disclosure.

Referring now to FIGS. 7-9, the frame assembly 104 a may include a frame160 rotatably supported by the shaft 118 a, for example. The frame 160may be fixedly or rotatably connected to the shaft 118 a in any suitablemanner, including bearings, flanges, couplings, fasteners, welds, seams,joints, or combinations thereof, for example. In some exemplaryembodiments of the inventive concepts disclosed herein an actuatormechanism, such as the actuator assembly 110, may be operably coupledwith the frame 160, with the shaft 118 a, with the support assembly 102a, and combinations thereof, and may rotate the frame 160 relative tothe shaft 118 a, the support assembly 102 a, or combinations thereof.

The frame 160 may have a first side 162 and a second side 164, the firstside 162 and the second side 164 oriented substantially parallel to oneanother, for example. It is to be understood that in some exemplaryembodiments of the inventive concepts disclosed herein, the first side162 and the second side 164 may be angled relative to one another at anydesired angle varying from about 0° to about 90°, for example. Further,in some exemplary embodiments the first side 162 or the second side 164may be omitted.

A rotation plane 166 (FIG. 9) may extend through the frame 160, and maybe oriented substantially parallel to the first side 162 and the secondside 164, for example. The rotation plane 166 may be orientedsubstantially vertically relative to a horizontal plane when the frameassembly 104 a is in a substantially vertical position, and may beangled relative to the horizontal plane when the frame assembly 104 a isin an angled position, for example.

In some exemplary embodiments of the inventive concepts disclosedherein, the frame 160 may be omitted, and the flow path assembly 106 amay be connected to the shaft 118 a, as will be appreciated by a personof ordinary skill in the art having the benefit of the instantdisclosure.

Referring back to FIGS. 3-4, the flow path assembly 106 a may beimplemented and function similarly to the flow path assembly 106, andmay include one or more fluid conduits 122 a-n cooperating to define asubstantially S-shaped flow path 108 a.

The conduits 122 a-n may be implemented as described above, and may bein fluid communication with one another so as to cooperate with oneanother to define the substantially S-shaped flow path 108 a, forexample. The conduits 122 a-n may be connected to the frame 160, so thata first portion of each conduit 122 a-n is connected to the first side162, and a second portion of each conduit 122 a-n is connected to thesecond side 164 of the frame 160, for example.

In the embodiment shown in FIG. 3-4, a portion of each conduit 122 a isshown as extending on either side of the plane 166 (FIG. 7) defined bythe frame 160. One or more upper bend 170 fluidly connecting twoadjacent conduits 122 is shown as intersecting the plane 166 (FIG. 7),and substantially U-shaped bottoms 172 of the conduits 122 a are shownas intersecting the plane 166 (FIG. 7), for example. It is to beunderstood that the upper bends 170 and the bottoms 172 may intersectthe plane 166 at any desired angle ranging from about 0° to about 90° insome exemplary embodiments. Further, in some exemplary embodiments, thebends 170 and the bottoms 172 may not intersect the plane 166 (FIG. 7),and may extend along the plane 166, or at a distance from the plane 166while being substantially coplanar with the plane 166. In some exemplaryembodiments, a first bend 170 or a first bottom 172 may intersect theplane 166, and a second bend 170 and a second bottom 172 may besubstantially coplanar with the plane 166. Further in other exemplaryembodiments, the conduits 122 a-n may intersect the plane 166, or may besubstantially coplanar with the plane 166 or combinations thereof, suchas a first conduit 122 a-n intersecting the plane 166, and a secondconduit 122 a-n being substantially coplanar with the plane 166.

An entry opening 124 may be formed in a first one of the conduits 122a-n, and an exit conduit 126 may be in fluid communication with a secondone of the conduits 122 a-n, for example, as described above.

One or more alternating first fluid column 140 and second fluid column142 may be positioned in the conduits 122 a-n as described above, forexample, so that a first fluid column 140 of the first fluid is trappedbetween two second fluid columns 142 of the second fluid in thesubstantially S-shaped flow path 108 a, as described above.

The apparatus 100 a may be initialized by filling the first portion ofthe conduits 122 a-n positioned on the first side 162 of the frame 160between about 50% and about 95% full of a first fluid having a firstdensity, while filling the second portion of the conduits 122 a-nconnected to the second side 164 of the frame 160 between about 5% andabout 50% full with the first fluid, for example. In some exemplaryembodiments, the first and the second portion of the conduits 122 a-nmay be filled to any desired volume or amount, such as between about 0%and about 100% full. In some exemplary embodiment, the second fluid maybe water, for example, although any suitable first fluid may be used solong as the first fluid has a first density that is higher than a seconddensity of a second fluid as will be described below.

The exact heights of the first fluid columns 142 that each of theconduits 122 a-n are filled to, are dependent on the pressure desired tobe outputted by the apparatus 100 a. This may result in a setup wherethe pressure in each conduit 122 a-n is increasing throughout the flowpath 108 a, with the initial pressure in the entry opening 124 beingatmospheric, and the pressure increasing in each subsequent alternatingfirst fluid column 140 and second fluid column 142, to the desired finalpressure at the exit conduit 126, for example.

While the pressure for the initial setup may be created by adding asecond fluid (e.g., air or gas) into each conduit 122 a-n, the pressureat any point in the substantially S-shaped flow path 108 a of theapparatus 100 a can easily be measured by looking at the differences inthe heights of the liquid in the first portion of the conduit 122 a-nconnected to the first side 162 of the frame 160 and the second portionof the conduit 122 a-n connected to the second side 164 of the frame160, for example. The initial setup is designed to have enough pressureto feed the desired pressure in the exit conduit 126, while also havingenough extra second fluid column 142 height to ensure that duringoperation the second fluid is not able to flow over the bends 170 of theconduits 122 a-n, or for the first fluid to be pushed under the bottoms172 of the conduits 122 a-n, for example.

To set up the apparatus 100 a the following procedure may be repeatedfor each side: Outlet valves (not shown) in fluid communication with thebottoms 172 may be substantially closed, while air valves (not shown) influid communication with the bends 170 may be substantially opened.

The apparatus 100 a may be positioned in the substantially verticalposition as shown in FIG. 3. A volume of the second fluid may be addedor removed to the vented conduits 122 a-n (e.g., via a port or a valvein fluid communication with each conduit 122 a-n), as described above.Vented second fluid levels may be determined by operation of theapparatus 100 a, and/or by pre-calculated tables or spreadsheets and maybe marked on the conduits 122 a-n of the apparatus 100 a for reference,in some exemplary embodiments.

At this point, the correct volume of the second fluid is present in theconduits 122 a-n, but the first fluid columns 140 are not at the desiredpressure. The air valves (not shown) in fluid communication with thebends 170 may be substantially closed.

The apparatus 100 a may be positioned in the angled position as shown inFIG. 4 by any suitable actuating mechanism, such as the actuatorassembly 110 a, as adding a volume of the first fluid at the angledposition is least problematic and may assure the minimum pressuredesired at the exit conduit 126 is present when the apparatus 100 a isin the angled position. First fluid column 140 heights or operationallevels may have been pre-established and marked on the conduits 122 a-nor in tables or spreadsheets which may indicated where the first fluidcolumn 140 heights for each conduit 122 a-n are desired to be at whenthe apparatus 100 a is in the angled position. A volume of the firstfluid may be added to each conduit 122 a-n, such as via ports or valvesin fluid communication with each conduit 122 a-n, for example.Alternatively, the first fluid may be added to the apparatus 100 a whilethe apparatus 100 a is in the substantially vertical position if carefulattention is given to add the first fluid to all conduits 122 a-nincrementally.

The risk involved in adding a too large volume of the first fluid in theapparatus 100 a is the potential to overcharge one conduit 122 a-n, andthen have a volume of the first fluid of the second fluid spill over toone or more adjacent conduits 122 a-n, for example. As will beappreciated by persons of ordinary skill in the art, because theconduits 122 a-n are in fluid communication with one another, adding avolume of the first fluid or the second fluid to any one of the conduits122 a-n affects the pressures and volumes of the first and the secondfluid in the remaining conduits 122 a-n. Readjustment (adding orremoving a volume of the first fluid or the second fluid) may be desiredto safely reach the predetermined operational pressure levels and firstfluid column 140 and second fluid column 142 heights in each conduit 122a-n, and in the flow path 108 a overall. Further, the charged levels ofthe first fluid columns 140 and the second fluid columns 142 when theapparatus 100 a is in the substantially vertical position do notrepresent the levels during output stroke, such as when a volume offluid is allowed to flow out of the exit conduit 126, for example.

Once the apparatus 100 a is set up, the next consideration is the outputresistance. If the exit conduit 126 is opened without any resistance tothe flow of fluids therethrough, the pressures inside each of theconduits 122 a-n in the apparatus 100 a will equalize, and the levelsand pressures of the first fluid columns 140 and the second fluidcolumns 142 in each conduit 122 a-n may be readjusted to optimal levelsas described above.

After initialization the apparatus 100 a is operated by removing avolume of fluid from the exit conduit 126 while the apparatus 100 a isin the substantially vertical position (FIG. 3). The actuator assembly110 a is then operated to rotate the apparatus 100 a to the angledposition (FIG. 4), and a volume of fluid is added back into the exitconduit 126. After the apparatus 100 a is returned to the substantiallyvertical position, the process can be repeated for as long as desired.The apparatus 100 a is configured to change the pressure of a fluidbetween two different values by being moved between the substantiallyvertical position (FIG. 3) and the angled position (FIG. 4). Thepressure change is accomplished by rotating the apparatus 100 a from thesubstantially vertical position to the angled position (e.g., betweenabout 5° and 85°) about the shaft 118 a. The exact angle of rotationbetween the substantially vertical position and the angled position maydepend on the difference between the higher and lower pressures desired,for example.

This rotation of the apparatus 100 a can be implemented via the actuatorassembly 110 a. It is to be understood that any suitable actuatormechanism or method may be used to effect the rotation of the apparatus100 a, and the optimal rotation may be dependent on the particularapplication for which the apparatus 100 a is used.

For example, a hydraulic actuator assembly 110 a as shown in FIG. 10 maybe implemented in some exemplary embodiments of the inventive conceptsdisclosed herein. The actuator assembly 110 a may be connected to theframe assembly 104 a and to the shaft 118 a of the apparatus 100 a, orto the frame assembly 104 a, for example. The actuator assembly 110 amay include a hydraulic arm 168. Exemplary embodiments of the actuatorassembly 110 a may also include one or more idler sprocket, drivesprocket (e.g., with a keyway), dual action hydraulic cylinder, drivechains with optional adjustable links for tension, locking collars onthe shaft 118 a to limit travel, and mounting plate and box frame foractuator assembly 110, for example.

Referring now to FIGS. 11A and 11B, shown therein is an exemplaryembodiment of an apparatus 100 b according to the inventive conceptsdisclosed herein. The apparatus 100 b may be implemented similarly tothe apparatus 100 a as described above, and may include a first set 180of conduits 122 a-n and a second set 182 of conduits 122 a-n, connectedto a support assembly 102 a, and offset from one another at an angle ofabout 90°, for example. It is to be understood that the first set 180and the second set 182 of conduits 122 a-n may be offset from oneanother at any desired angle varying from about 0° to about 180°, fromabout 45° to about 135°, from about 70° to about 80°, or combinationsand sub-combinations thereof, in some exemplary embodiments. In someexemplary embodiments the first set 180 and the second set 182 ofconduits 122 a-n may be offset from one another at an angle of about75°, or at any other angle.

The conduits 122 a-n in the first set 180 may be in fluid communicationwith one another and may cooperate to define a substantially S-shapedflow path 108 b, for example. The conduits 122 a-n in the second set 182may be in fluid communication with one another and may cooperate todefine a substantially S-shaped flow path 108 c, for example.

The first set 180 may be in fluid communication with a first exitconduit 186, and the second set 182 may be in fluid communication with asecond exit conduit 188. The first exit conduit 186 and the second exitconduit 188 may be implemented and function similarly to the exitconduit 126, for example.

The apparatus 100 b may further include an actuator assembly (notshown), which may be implemented and function similarly to the actuatorassembly 110 or the actuator assembly 110 a as described above, forexample.

In operation, the apparatus 100 b may be set up and initialized asdescribed above with reference to the apparatus 100 a, for example. Theoutputs of the first exit conduit 186 and the second exit conduit 188are desirably kept separate. The orientation of the first set 180 andthe second set 182 relative to one another enables the sets 180 and 182to alternate between a substantially vertical position (e.g., relativelyhigh-pressure) and an angled position (e.g., relatively low-pressure) asthe apparatus 100 b is tilted, so that when the first set 180 is in thesubstantially vertical position, the second set 182 is in the angledposition, and vice versa, for example. This would allow for a volume offluid to be removed from the set (e.g., 180 or 182) that is in thesubstantially vertical position, while simultaneously allowing for avolume of fluid to be reintroduced in the set (e.g., 180 or 182) that isin the angled position. This process may be repeated as long as desired,as described above. As will be appreciated by a person or ordinary skillin the art, the apparatus 100 b may be operated in a forward-reversedirection to alternatively position the first set 180 and the second set182 in the substantially vertical and the angled positions as indicatedby the arrows in FIGS. 11A-11B. However, in some exemplary embodiments,the apparatus 100 b may be rotated at 180° or at 360° or more as will bedescribed herein below.

Referring now to FIGS. 12A-12B, an exemplary embodiment of a rotaryapparatus 100 c according to the inventive concepts disclosed herein maybe implemented similarly to the apparatus 100 b described above and mayinclude four sets 190 a-d of conduits 122 a-n (with only one set 190 ashown in FIG. 12A shown for clarity). The four sets 190 a-d may beattached to a frame assembly 104 c, and to a support assembly 102 c, andmay be offset from one another at an angle α, which may vary from about0° to about 45°, for example. As will be appreciated by a person ofordinary skill in the art, a first angle separating a first set 190 aand a second set 190 b, and a second angle separating the second set 190b and a third set 190 c may be different, similar, or substantiallyequal to one another, and combinations thereof. Further, any number ofsets 190 may be used with the inventive concepts disclosed herein, suchas one, two, three, or more than four sets 190, for example.

The sets 190 a-d may each include an entry opening 124 a-d and an exitconduit 126 a-d. The entry openings 124 a-d, and the exit conduits 126a-d may be implemented and function similarly to the entry opening 124and the exit conduit 126 respectively, for example.

The exit conduits 126 a-d are in fluid communication with a manifold194. The manifold 194 may be implemented as a Dublin union in someexemplary embodiments of the inventive concepts disclosed herein, andmay be implemented such that rotational flow of fluid provided from theexit conduits 126 a-d is diverted between the exit conduits 126 a-d, forexample by utilizing one or more fluid ports (not referenced) configuredto divert the flow at any angle, such as an angle varying between about0° and about 360°, or between about 45° and about 90°, at about 75°, orany combinations and sub-combinations thereof, for example. The manifold194 may be configured so as to place a first set 190 a in fluidcommunication with a third set 190 c, and a second set 190 b in a fluidcommunication with a fourth set 190 d, for example. It is to beunderstood that any of the sets 190 a-d may be in fluid communicationwith any other sets 190 a-n, and all sets 190 a-d may be in fluidcommunication with one another in some exemplary embodiments.

As will be appreciated by a person of ordinary skill in the art, Dublinunions are standard devices that are configured to allow flow to travelfrom a rotational object to a stationary object without leaking, such asvia maintaining a rotational and sealed fluid connection with therotational object.

The frame assembly 104 c may include a shaft 118 c, and may have an axis200 extending substantially along the shaft 118 c in some exemplaryembodiments.

An optional generator 202 may be operatively coupled with the shaft 118c, such as via a gear system 204, for example, so that rotational motionof the shaft 118 may be converted to electrical energy by the generator202, for example. The generator 202 may be implemented as any suitablegenerator 202 such as an electromagnetic motor or generator 202, forexample. The gear system 204 may be implemented as any suitable gearsystem 204 configured to convey mechanical energy from the shaft 118 cto the generator 202, for example. In some exemplary embodiments, thegear system 204 may be omitted, and any suitable mechanical system maybe implemented, such as a belt system, a chain drive system, a camshaftand crankshaft system, a worm drive system, and combinations thereof.Further, in some exemplary embodiments of the inventive conceptsdisclosed herein a shaft of the generator 202 may be connected to theshaft 118 c, as will be appreciated by persons of ordinary skill in theart.

An optional braking mechanism (not shown) may be implemented with theinventive concepts disclosed herein, and may be operably coupled withone or more of the shaft 118 c, the gear system 204, or the generator202 so as to control the speed at which the shaft 118 c, the gear system204, and the generator 202 rotate, for example.

Referring now to FIGS. 13A, in some exemplary embodiments of theinventive concepts shown herein multiple sets 190 a-d may be positionedalong the same shaft 118 d and may be offset relative to one another atany desired angle β, which may vary from about 0° to about 360°, forexample.

In operation, each set 190 a-d of the apparatus 100 c may be set up andmay operate similarly to the apparatus 100, 100 a, or 100 b above.

The flow of first or second fluids between each of the sets 190 a-d isrestricted (e.g., being mechanical float-checked) at the point thelowest pressure is reached in each of the sets 190 a-c—thissubstantially prevents the first and second fluids from blowing over orspilling over, and may also cause an uneven weight distribution to occurduring the setup of the apparatus 100 c.

In some exemplary embodiments, a second manifold such as the manifold194 may be placed in fluid communication with the entry openings 124 a-dand may be configured to be accessed during the certain range ofrotation, meaning only two fluid ports may be implemented with thesecond manifold 194, for example.

In the design of exemplary embodiment of an apparatus 100, 100 a, 100 b,or 100 c according to the inventive concepts disclosed herein severaldesign criteria may be useful to ensure that the respective apparatus isconfigured to fluctuate between a desired high and a low pressure withthe desired amount of fluid being removed and without blowing over(e.g., having the second fluid spillover the top of a conduit or thefirst fluid pass under a conduit).

The height and number of conduits used are related, since they are bothused to control the maximum pressure that an apparatus constructed inaccordance with the inventive concepts disclosed herein can reach. Sincethe pressure in an apparatus is a function of the of the vertical fluidcolumn heights, the pressure in a first fluid column can be determinedby looking at the summation of the differences between each of the highand low second fluid column heights in each conduit of the S-shaped flowpath. This makes it where the total height of an apparatus can be cutdown by using multiple conduits to define the S-shaped flow path. Forany desired pressure, the total height of an apparatus is inverselyproportional to the number of conduits used to define the s-shaped flowpath.

The diameter of the substantially S-shaped flow path may be controllednot by the desired pressures, but instead by the volume of a first fluidor a second fluid that is desired to be moved by the apparatus. Since avolume of the first fluid or the second fluid is being removed from theapparatus, this changes the heights of the first and second fluidcolumns within the apparatus. The effect that this volume change has onthe first and second fluid column heights is inversely proportional tothe internal diameter of the flow path. But, a larger flow path diameterleads to a heavier apparatus that is harder to operate and is lessefficient. Because of this, the diameter of the flow path may beselected to be as small as is available to ensure that the apparatusoperates within the desired factor of safety.

In some exemplary embodiments, another desirable design criterion is theangle or radians of rotation of an apparatus constructed according tothe inventive concepts disclosed herein. This angle may be designed tocontrol the difference between the high and low pressure inside thesubstantially S-shaped flow path of the apparatus. As the apparatustilts or rotates from a substantially vertical position towards anangled position, the vertical fluid column heights of the first fluidand the second fluid are reduced, which causes the pressure inside theflow path to decrease. Since the high pressure is determined by theinitial set up of the apparatus, the angle of rotation may be utilizedto determine the minimum pressure inside the flow path at which theapparatus may be operated, for example.

An additional issue with some exemplary embodiments of an apparatusaccording to the inventive concepts disclosed herein that is to be takeninto consideration when designing an apparatus is spillover. Spillovercan occur in two different ways. The first cause of spillover happens ifany of the first fluid column heights are allowed to drop below thebottom bends in the conduits defining the substantially S-shaped flowpath. If this happens, a volume of the first fluid may pass from a firstconduit to a second adjacent conduit. Spillover can also occur if thesecond fluid column height in any of the conduits is allowed to riseabove the safe limits, and transfer over the top bend from a firstconduit to an adjacent second conduit, for example. If either of thesespillover conditions occurs the dynamics of the apparatus may be changedand the apparatus may be desirably re-initialized before it performsoptimally. Because of this issue, it is important to selecting sizingfor a particular apparatus such that the first and the second fluidcolumn heights do not approach the spillover points. Because anapparatus constructed according to the inventive concepts disclosedherein may have varying sizes, volumes, and heights, and may usedifferent first and second fluids, such spillover limits may beempirically determined and clearly marked on the apparatus and/orincluded with an accompanying manual or set up procedure description,for example.

From the above description, it is clear that the inventive conceptsdisclosed herein are adapted to carry out the objects and to attain theadvantages mentioned herein as well as those inherent in the inventiveconcepts disclosed herein. While presently preferred embodiments of theinventive concepts disclosed herein have been described for purposes ofthis disclosure, it will be understood that numerous changes may be madewhich will readily suggest themselves to those skilled in the art andwhich are accomplished within the scope of the inventive conceptsdisclosed herein and defined by the appended claims.

What is claimed is:
 1. An apparatus, comprising: a base; a flow pathassembly movably supported by the base and defining a substantiallyserpentine flow path having an entry opening and an exit opening; anactuator coupled with the flow path assembly and with the base, theactuator configured to rotate the flow path assembly between asubstantially vertical position and an angled position relative to thebase; and wherein the substantially serpentine flow path is configuredto allow a column of a first fluid with a first density to be trappedbetween two columns of a second fluid with a second density higher thanthe first density, the first fluid column having a first height and thesecond fluid columns having second heights, so that a first volume ofthe first fluid and a second volume of the second fluid flow in and outthe serpentine flow path through the exit opening as the flow pathassembly is rotated between the substantially vertical position and theangled position.
 2. The apparatus of claim 1, wherein the entry openingis in fluid communication with the atmosphere.
 3. The apparatus of claim1, further comprising a tank fluidly connected to the exit opening andconfigured to hold the first and second volume of fluid as the first andsecond fluids are moved through the exit opening.
 4. The apparatus ofclaim 1, wherein the substantially serpentine flow path rotates betweenabout 0° and about 35° relative to the base when the flow path assemblyis rotated between the substantially vertical position and the angledposition.
 5. The apparatus of claim 1, wherein the actuator comprises ahydraulic arm connected to the flow path assembly.
 6. An apparatus,comprising: a base; a frame movably supported by the base, the framehaving a first side and a second side cooperating to define a rotationplane and a rotation axis extending substantially parallel to therotation plane, the frame being rotatable between a substantiallyvertical position and an angled position about the rotation axis; anactuator assembly coupled with the frame and with the base, the actuatorassembly configured to rotate the frame about the rotation axis betweenthe substantially vertical position and the angled position relative tothe base; a flow path assembly, comprising: a first conduit having afirst upper end and a first lower end and being connected to the frameso that the first conduit extends substantially vertically when theframe is in the substantially vertical position; a second conduit havinga second upper end and a second lower end and being connected to theframe so that the second conduit extends substantially vertically whenthe frame is in the substantially vertical position; a third conduithaving a third upper end and a third lower end and being connected tothe frame so that the third conduit extends substantially verticallywhen the frame is in the substantially vertical position; a fourthconduit having a fourth upper end and a fourth lower end and beingconnected to the frame so that the fourth conduit extends substantiallyvertically when the frame is in the substantially vertical position; afirst connector conduit fluidly connected with the first lower end ofthe first conduit and the second lower end of the second conduit, thefirst connector conduit having a first fluid passage formed therein andconfigured to allow one or more fluids to be introduced into, or removedfrom, the first and the second conduits; a second connector conduitfluidly connected with the second upper end of the second fluid conduitand the third upper end of the third conduit, the second connectorconduit having a second fluid passage formed therein and configured toallow one or more fluids to be introduced into or removed from thesecond connector conduit; a third connector conduit fluidly connectedwith the third lower end of the third conduit and the fourth lower endof the fourth conduit, the third connector conduit having a third fluidpassage formed therein and configured to allow one or more fluids to beintroduced into or removed from the third connector conduit; and an exitconduit fluidly connected with the fourth upper end such that the first,second, third, and fourth conduits, the first, second, and thirdconnector conduits, and the exit conduit, cooperate to define asubstantially serpentine flow path; and wherein the substantiallyserpentine flow path is configured to allow a column of a first fluidwith a first density to be trapped between two columns of a second fluidwith a second density higher than the first density, the first fluidcolumn having a first height and the second fluid columns having secondheights, so that a first volume of the first fluid and a second volumeof the second fluid flow in and out the serpentine flow path through theexit conduit as the frame is rotated between the substantially verticalposition and the angled position.
 7. The apparatus of claim 6, whereinthe first upper end of the first conduit is in fluid communication withthe atmosphere.
 8. The apparatus of claim 6, further comprising a tankfluidly connected to the exit conduit and configured to hold the firstand second volume of fluid as the first and second fluids are movedthrough the exit conduit.
 9. The apparatus of claim 6, wherein therotating plane is moved between about 0° and about 35° when the frame isrotated between the substantially vertical position and the angledposition.
 10. The apparatus of claim 6, wherein the actuator assemblycomprises a hydraulic arm connected to the frame.
 11. The apparatus ofclaim 6, wherein the first and the third conduits are connected to thefirst side of the frame, and the second and fourth conduits areconnected to the second side of the frame.
 12. The apparatus of claim11, wherein the first, second, and third connector conduits and the exitconduit extend through the plane defined by the first and the secondside of the frame.
 13. The apparatus of claim 6, further comprising: afirst column of the first fluid positioned in the first conduit; a firstcolumn of a second fluid positioned at least partially in the firstconduit and in the first connector conduit; a second column of the firstfluid positioned in the second connector conduit and at least partiallyinto the second conduit, the first connector conduit, and the thirdconduit; a second column of the second fluid positioned at leastpartially in the second conduit and at least partially in the thirdconnector conduit; a third column of the first fluid positioned at leastpartially into the third conduit and at least partially into the fourthconduit; and wherein the substantially serpentine flow path isconfigured to allow the third column of the first fluid to be trappedbetween the first and second columns of the second fluid, so that afirst volume of the first fluid and a second volume of the second fluidthrough the serpentine flow path as the frame is rotated between thesubstantially vertical position and the angled position.
 14. Theapparatus of claim 6, wherein the substantially vertical position andthe angled position are separated by an angle ranging between about 0°and about 45°.
 15. The apparatus of claim 6, wherein the substantiallyvertical position and the angled position are separated by an angleranging between about 0° and about 360°.
 16. The apparatus of claim 6,wherein the substantially vertical position and the angled position areseparated by an angle ranging between about 0° and about 180°.